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sunmaz94
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Homework Statement
Let A, B, and C be sets. Assume the standard ZFC axioms.
Please see below for my updated question.
Thanks.
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Dick said:Pick A={a}. Pick B={A}={{a}}. So A ε B. Correct so far? Pick C={B}={{{a}}}. So B ε C. Is A ε C?? This is a little tricky. a is not equal to the set consisting of a.
sunmaz94 said:Yes I understand this. But how does the chain of set inclusions I mention lead to the fact that C ε C?
(Thanks for all your help!)
Dick said:You seem to have deleted the question. I thought I suggested you try to prove that A ε B and B ε C doesn't necessarily imply A ε C? Since inclusion is not transitive?
sunmaz94 said:I agree. I am now asking modified question: How then can I show that if A ε B and B ε C and C ε A, that C ε C (yields the contradiction I require).
Apologies for the confusion.
Dick said:I think you are reaching way too far for a contradiction. C ε C puts you squarely in Bertrand-Russell paradox territory. A simple example of A ε B and B ε C with simple sets and A not an element of C will serve nicely. I basically gave you one. Follow it up.
sunmaz94 said:This is a separate question. I absolutely want to be in such territory. I need to show that the aforementioned set inclusions yield C ε C and then I can invoke the axiom of regularity/foundation to show it is a contradiction.
Dick said:I don't think so. Inclusion ISN'T transitive. You can't say A ε B and B ε C implies A ε C. At all.
sunmaz94 said:Hmm...
Then how do I go about using the axiom of regularity to prove that no set membership loops like that I described exist?
Dick said:C ε C already violates regularity. The statement C ε C doesn't follow from anything you've said before because inclusion isn't transitive.
sunmaz94 said:Yes but I want to show that A ε B and B ε C and C ε A violates regularity.
Dick said:Mmm. I'm not all that hot with set axiomatics. But you can simplify that. Suppose A ε B and B ε A, can you show that violates regularity?? Like I say, I don't have ZFC axioms at my fingertips.
The transitivity of an element refers to its ability to be inherited or passed down through a series of related elements or objects. In other words, if element A is transitive, then any element that is related to element A will also possess the same properties or qualities.
The transitivity of an element can be determined by examining its relationships with other elements. If an element has a clear pattern of inheritance or transfer of properties to related elements, then it can be considered transitive.
An example of a transitive element is the chemical element Carbon. Carbon has the ability to form bonds with many other elements, such as hydrogen, oxygen, and nitrogen. These bonds are transitive, meaning the properties of carbon are transferred to the bonded elements, resulting in new compounds with similar qualities.
Yes, an element can exhibit partial transitivity. This means that the element may have some relationships where its properties are transferred, but not all. This can be seen in elements with multiple oxidation states, where the properties may differ depending on the elements it is bonded to.
The transitivity of an element is an important concept in scientific research, particularly in fields such as chemistry and biology. Understanding the transitivity of an element allows scientists to predict and analyze the properties of related elements and compounds, aiding in the development of new materials and medicines.